Modelling of mechanical system CREATING OF KINEMATIC CHAINS

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1 Modelling of mechanical system CREATING OF KINEMATIC CHAINS

2 Mechanism Definitions 1. a system or structure of moving parts that performs some function 2. is each system reciprocally joined moveable bodies the bodies we call members or link (they can be rigid, elastic, flexible etc.)

3 Degrees of Freedom The system's DOF is equal to the number of independent parameters (measurements) which are needed to uniquely define its position in space at any instant of time. A rigid body in plane motion has three DOF. Any rigid body in three-space has six degrees of freedom

4 Types of motions A rigid body free to move within a reference frame will, in the general case, have complex motion, which is a simultaneous combination of rotation and translation. In three-dimensional space, there may be rotation about any axis and also simultaneous translation which can be resolved into components along three axes. In a plane, or two-dimensional space, complex motion becomes a combination of simultaneous rotation about one axis (perpendicular to the plane) and also translation resolved into components along two axes in the plane. We will limit our present discussions to the case of planar (2-D) kinematic systems.

5 Types of motions Pure rotation: the body possesses one point (center of rotation) which has no motion with respect to the "stationary" frame of reference. All other points on the body describe arcs about that center. A reference line drawn on the body through the center changes only its angular orientation. Pure translation: all points on the body describe parallel (curvilinear or rectilinear) paths. A reference line drawn on the body changes its linear position but does not change its angular orientation. Complex motion: a simultaneous combination of rotation and translation. Any reference line drawn on the body will change both its linear position and its angular orientation. Points on the body will travel nonparallel paths, and there will be, at every instant, a center of rotation, which will continuously change location.

6 Links, Joints and Kinematic Chains A link is an (assumed) rigid body which possesses at least two nodes which are points for attachment to other links. A link which is connected to two other links is called a binary link A link which is connected to three other links is called a ternary link A link which is connected to four other links is called a quaternary link

7 Links, Joints and Kinematic Chains Some of the common types of links are: Binary link - one body with two nodes. Ternary link - one body with three nodes. Quaternary link - one body with four nodes. Pentagonals one body with five nodes. Hexagonals one body with six nodes

8 Links, Joints and Kinematic Chains A joint is a connection between two or more links (at their nodes), which allows some motion (or potential motion) between the connected links. Joints (also called kinematic pairs) can be classified in several ways: 1. By the number of degrees of freedom allowed at the joint. 2. By the type of contact between the elements, line, point, or surface. 3. By the type of physical closure of the joint: either force or form closed. 4. By the number of links joined (order of the joint).

9 Links, Joints and Kinematic Chains 1. Classification by the Number of Degrees of Freedom allowed at the joint We can classify Joints by the number of degrees of freedom allowed at the joint as: One-Freedom Joints or Full Joints - examples of one freedom joints are a rotating pin joint (R) or a translating slider Joint (P). Two Freedom Joints or Half Joints - examples of two freedom joints are link against plane or a pin in slot (C). Three Freedom Joints - examples of three freedom joints are a spherical (G) or ball-and-socket joints.

10 Links, Joints and Kinematic Chains 1. Classification by the Number of Degrees of Freedom allowed at the joint R Revolute pair i=1 (a) P Prismatic pair i=1 (b) S Screw pair i=1 (c) a) Relative movement is rotational movement about an axis defined by the coordinate ψ. b) Relative movement is movement in the axial direction of the pin defined by the coordinates s. c) Relative movement of the screw is defined by the coordinate ψ rotational movement around the screw axis or coordinate s with the sliding movement in the axial direction of the screw. Coordinates ψ,h are bonded where h is the stroke of the bolt in one revolution..

11 Links, Joints and Kinematic Chains 1. Classification by the Number of Degrees of Freedom allowed at the joint G Spheric pair i=3 (d) C Cylinder pair i=2 (a) F Planar pair i=3 (f) d) Relative motion is defined by a spherical three coordinates: two coordinates α, ϕ specify the direction of the axis of rotation and are ψ of rotation about the axis. e) Relative movement is a combination of rotational movement about the axis of the cylinder and sliding along the cylinder axis; corresponding coordinates are ψ, s. f) Relative movement is composed of two displacements x, y, ψ of rotation about an axis perpendicular to the plane of movement.

12 Links, Joints and Kinematic Chains 2. Classification by the Type of Contact between elements We can classify Joints by the type of contact as Lower Pairs or Higher Pairs. If joints have surface contact, they are called Lower pair (as with a pin surrounded by a hole). If joints have point or line contact, they are called Higher pair. The main practical advantage of lower pairs over higher pairs is their better ability to trap lubricant between their enveloping surfaces. Higher Kinematic Pairs Line Contact (a) Point Contact (b)

13 Links, Joints and Kinematic Chains 2. Classification by the Type of Contact between elements The six possible lower pairs are: Revolute (R), Prismatic (P), Screw/Helical (H), Cylindric (C), Spherical (G), Flat (F).

Links, Joints and Kinematic Chains 3. Classification by the Type of Physical Closure of the Joint We can classify Joints by the type of physical closure of the joint as Force closed or Form closed.

14 Links, Joints and Kinematic Chains 3. Classification by the Type of Physical Closure of the Joint We can classify Joints by the type of physical closure of the joint as Force closed or Form closed. A form closed joint is kept together or closed by its geometry. A pin in a hole or a slider in a two-sided slot are form closed. In contrast, a force-closed joint, such as a pin in a halfbearing or a slider on a surface, requires some external force to keep it together or closed. This force could be supplied by gravity, a spring, or any external means. form closed joint force-closed joint

15 Links, Joints and Kinematic Chains 4. Classification by the Order of Joints We can classify Joints by the order of joints as 1st order, 2nd order and so on. Order is defined as the number of links joined minus one. It takes two links to make a single joint; thus the simplest joint combination of two links has order one. Joint order has significance in the proper determination of overall degree of freedom for the assembly.

16 Links, Joints and Kinematic Chains Kinematic chain : It is a combination of several successively arranged joints constituting a complex motor system. The kinematic chain may be: - open or closed - simple or composite - Free or fixed - Planar or spatials (trajectories are planar or spatial curves)

17 Links, Joints and Kinematic Chains The kinematic chain may be open or closed. In a closed kinematic chain, the distal segment is fixed and the end segments are unite to form a ring or a circuit. When one link moves all the other links will move in a predictable pattern. In an open kinematic chain, the distal segment terminates free in space.

18 Links, Joints and Kinematic Chains The kinematic chain may be simple or composite. (composite one member joints with three and more kinematic pairs) The kinematic chain may be free or fixed.

19 Spatial Kinematic Chain A system of n rigid bodies moving in space has 6n degrees of freedom. Kinematic pairs (joints) that connect bodies in the system remove degrees of freedom and reduce mobility. The result is that the mobility of a system formed from n moving links and d kinematic pairs each with freedom i j, j = 1,..., d, is given by I degrees of freedom of a spatial kinematic chain n number of members/links of kinematic chain (with frame) d number of kinematic pairs i j degrees of freedom of j-kinematic pairs

20 Spatial Kinematic Chain R Revolute pair i=1 (a) P Prismatic pair i=1 (b) S Screw pair i=1 (c) G Spheric pair i=3 (d) C Cylinder pair i=2 (a) F Planar pair i=3 (f)

21 Spatial Kinematic Chain Spatial four-bar linkage with revolute kinematic pairs only wrong option

22 Spatial Kinematic Chain Spatial four-bar linkage good option

23 Spatial Kinematic Chain Spatial crank mechanism

24 Spatial Kinematic Chain

25 Spatial Kinematic Chain

26 Kinematic Chain Literature: Ashok G. Ambekar: Mechanism and machine theory. PHI Learning private Limited. Delhi

Kinematics Fundamentals CREATING OF KINEMATIC CHAINS

Kinematics Fundamentals CREATING OF KINEMATIC CHAINS Mechanism Definitions 1. a system or structure of moving parts that performs some function 2. is each system reciprocally joined moveable bodies the